Nuclear medicine is the use of radioactive substances in the diagnosis and treatment of disease. Nuclear medicine records the radiation that is emitting from the body, unlike x-rays which determine the radiation emitted by external objects. Nuclear medicine scans show the function of anatomy and are known as a physiological imaging modality. The two most common forms of nuclear medicine are “SPECT” single photon emission computed tomography and “PET” positron emission tomography. In nuclear medicine, there are several different types of procedures that a patient could prepare for. In most cases, the physician will provide instructions for necessary preparation. Most patients will be given a small dose of radioisotope either by injection or orally to magnify visualization. When radiation procedures involve thing such as bones, and the brain special preparation is not needed. Most of the time a patient will wear a gown before the radiation procedure. …show more content…
Radiation such as x rays can make it easier to look at different parts of the body to identify any diseases that are growing or spreading. Nuclear medicine makes it easier for doctors to treat their patients. They provide accurate results. Nuclear medicine can be a benefit, but it also has some disadvantages. It can be very costly as nuclear medicine is not cheap for the patient or the industry. It can also cause health issues especially in elderly, pregnant women, and younger individuals. Many different types of diseases are treated with a nuclear medicine like different types of cancers, thyroid disease, Parkinson’s disease, epilepsy, and Alzheimer’s disease. These are just a few diseases nuclear medicine can
the effective doses from diagnostic CT procedures are typically estimated to be in the range of 1 to 10 mSv. This range is not much less than the lowest doses of 5 to 20 mSv estimated to have been received by some of the Japanese survivors of the atomic bombs. These survivors, who are estimated to have experienced doses slightly larger than those encountered in CT, have demonstrated a small but increased radiation-related excess relative risk for
When taking a radiograph there are some precautions that can be taken to reduce some of the radiation that can be exposed to a patient, what would be used on all patients is call a lead apron and thyroid collar, these aprons are used to protect the patients that may be a bit more radiosensitive and also may give the patient a little of reassurance that they will be protected. “Radiosensitivity is the relative susceptibility of cells, tissues, organs, organisms, or other substances to the injurious action of radiation.”
Nuclear energy is used today for energy supply and about 15% of the world’s energy comes from nuclear power plants some forms of medicine such as nuclear medicine rely solely on nuclear technology. This technology was developed through the process of creating the first atomic bomb and would not exist if not for the advancements made during the Manhattan project.
The role of the radiologist is one that has undergone numerous changes over the years and continues to evolve a rapid pace. Radiologists specialize in the diagnoses of disease through obtaining and interpreting medical images. There are a number of different devices and procedures at the disposal of a radiologist to aid him or her in these diagnoses’. Some images are obtained by using x-ray or other radioactive substances, others through the use of sound waves and the body’s natural magnetism. Another sector of radiology focuses on the treatment of certain diseases using radiation (RSNA). Due to vast clinical work and correlated studies, the radiologist may additionally sub-specialize in various areas. Some of these sub-specialties include breast imaging, cardiovascular, Computed Tomography (CT), diagnostic radiology, emergency, gastrointestinal, genitourinary, Magnetic Resonance Imaging (MRI), musculoskeletal, neuroradiology, nuclear medicine, pediatric radiology, radiobiology, and Ultrasound (Schenter). After spending a vast amount of time on research and going to internship at the hospital, I have come to realize that my passion in science has greatly intensified. Furthermore, both experiences helped to shape up my future goals more prominently than before, which is coupled with the fact that I have now established a profound interest in radiology, or rather nuclear medicine.
The description of PET scans in detail requires the understanding of the radioactive substance injected into the subject. First, a small amount of a biochemical substance is tagged with a positron-emitting radioisotope. A positron is an “anti-electron.” Positrons are given off during the decay of the nuclei of the radioisotope. When the positron emitted collides with an electron in the tissue of the subject, both the positron and the electron are annihilated. When this happens, the collision produces two gamma rays having the same energy (511 KeV), but going in opposite directions.
There are essentially three main types of cancer treatments; surgery, chemotherapy, and radiation. Surgery allows doctors to effectively remove tumors from a clear plane. Chemotherapy uses drugs to treat the tumor; but often the drugs affect other healthy cells in the process. Using radiation as a treatment can be either precise or vague. Many health stigmas can come from the vague forms of radiation or conventional radiation therapy. Conventional radiation treats both the unhealthy and healthy cells, therefore exposing healthy cells to harmful radiation (Radiation Oncology, 2011, p.6). When healthy cells are exposed to gamma radiation they are also exposed to ionizing radiation. The ionization can cause “breakage of chemical bonds or oxidization (addition of oxygen atoms)” in a cell; the main impact of this is on a cell’s DNA, if two strands of DNA break it can result in “mutations, chromosome aberrations, ...
“External radiation uses a machine that directs high-energy rays from outside the body into the tumor and some normal nearby tissue.” (American Cancer Society p. 5) After this treatment the patient will not be radioactive, but treatment is delivered in small doses and can last several weeks. “Internal radiation or brachytherapy, uses a radioactive source, called an implant, that’s put inside the body in or near the tumor.” (American Cancer Society p. 9) It may be placed in an organ or in the cancerous tumor. The patient will be radioactive for a short time. Due to the implant being near the source of cancer a larger dose can be delivered to the patient. “Systemic radiation uses radioactive drugs to treat certain type of cancer.” (American Cancer Society p. 12) The drugs used are called radiopharmaceuticals and can be delivered orally or intravenously. “They collect where the cancer is to give off their radiation and kill the cancer cells.” (American Cancer Society p. 12) After this treatment the patient will be radioactive, and will take a few days to be removed from the patients
What is radiology? Radiology is a branch of medical science that makes the use of radiation and radioactive materials. Radiology is related to energy- related physical phenomena in the diagnosis and treatment of particular diseases. Two major therapy- related areas of radiology are so- called therapeutic radiology. Therapeutic radiology deals particularly with the use of ionizing radiation is to treat cancer, and interventional radiology, Which radiological imaging techniques are used to assist various minimally invasive surgical procedures.
As a starting point in CT diagnostic imaging the form of radiation used to provide an image are x-rays photons , this can also be called an external radiation dose which detect a pathological condition of an organ or tissue and therefore it is more organ specific. However the physics process can be described as the radiation passes through the body it is received by a detector and then integrated by a computer to obtain a cross-sectional image (axial). In this case the ability of a CT scanner is to create only axial two dimensional images using a mathematical algorithm for image reconstruction. In contrast in RNI the main property for producing a diagnostic image involves the administration of small amounts of radiotracers or usually called radiopharmaceutical drugs to the patient by injection or oral. Radio meaning the emitted of gamma rays and pharmaceutical represents the compound to which a nuclide is bounded or attached. Unlike CT has the ability to give information about the physiological function of a body system. The radiopharmaceutical often referred to as a nuclide has the ability to emit ga...
Radiation therapists work closely with patients to fight cancer. According to Health Care Careers, Oncologists, Dosimetrists and nurses are some of the professionals that a radiation therapist works with while caring for a cancer patient. This group of professionals will determine a specialized treatment plan. The first step usually includes a CT scan performed by a radiologist to find the exact area that needs to be targeted with x-rays. Next, the therapist uses a special machine that emits radiation called a Linear Accelerator. They use this machine during a treatment called external beam therapy. During this process, the Linear Accelerator will project x-rays at targeted cancer cells or tumors. Another therapist will be in a different room monitoring the patient’s viral signs until the procedure is over. The external therapy l...
Nuclear Medicine is the use of radioisotopes for diagnosis, treatment, and research. Radioactive chemical tracers emit gamma rays which provides diagnostic information about a person's anatomy and the functioning of specific organs. Radioisotopes are also utilizes in treatments of diseases such as cancer. It is estimated that approximately one in two people in Western countries are likely to experience the benefits of nuclear medicine in their lifetime.
A radioisotope is an isotope that emits radiation as it has nuclear instability(Prostate Cancer; Fusion imaging helps target greater doses of radiation).Those who are not too familiar with radioisotopes may think their use is for harmful radiation, nuclear weapons, and the possibility of turning into a giant, raging, green monster. However, there are much more positive uses for radioisotopes. There have been many medical advances thanks to the benefit and practice of radioisotopes in nuclear medicine. These advances have been able to diagnose and treat a variety of diseases.
Nuclear engineers commonly find solutions to technical problems involving nuclear materials. The engineer’s main role is to “…research and develop the processes, instruments, and systems used to derive benefits from nuclear energy and radiation (elibrary.bigchalk.com).” They find applications for radioactive technology, such as developing new equipment in the medical field that use radiation. In addition to the discussed usage of these applications in medicine, other uses are in power generation, and military. Nuclear engineers work in all steps of the nuclear process, from nuclear material mining until the disposal of waste (jobdescriptions.net).
Technetium is a commercial radioisotope produced in the OPAL reactor at ANSTO and is used in the medical industry since its properties are ideal for its use. Technetium-99m is used for 80% of Australia’s nuclear medical scans, detecting disease in lungs, heart, liver, kidney, brain, blood and skeleton. Technetium-99m is used as a radioactive tracer which is injected to the patient where it will accumulate in any problem areas and can be detected by the gamma radiation given off by nuclear imaging. Using Nuclear Imaging to obtain a scan, doctors can detect the presence of secondary bone
Nuclear energy is generated by a process called fission. Fission occurs within the reactor of a nuclear power plant when a neutron is fired at an atom of uranium causing it to split and release subsequent neutrons.1 These are able to crash into other uranium atoms causing a chain reaction and releasing a great deal of heat energy.